Published by Oriental Scientific Publishing Company © 2019
This is an Open Access article licensed under a Creative Commons license: Attribution 4.0 International (CC-BY).
Antimicrobial, Antioxidant, Total Phenols and Flavonoids
Content of Four Cactus (
Opuntiaficus-indica
) Cultivars
Ahlem Bargougui1,2*, Hend Maarof Tag1,3*, Mohamed Bouaziz4 and Saida Triki2
1Department of Biology, Faculty of Sciences and Arts-Khulais, University of Jeddah, PO Box 355, ISIN Code 21-921, Jeddah, Saudi Arabia.
2Laboratory of Biochemistry, Faculty of Science, University El Manar Campus PO Box 2092 Tunis, Tunisia.
3Department of Zoology, Faculty of Sciences, Suez Canal University, PO Box 41522, Egypt. 4Laboratory of Electrochemistry and Environment, Higher Institute of Biotechnology of Sfax,
University of Sfax, PO Box 1175, 3038 Sfax, Tunisia. *Corresponding authors E-mail: bargouguiahlem@yahoo.fr
http://dx.doi.org/10.13005/bpj/1764
(Received: 22 July 2019; accepted: 22 August 2019)
Opuntiaficus-indica is a cactus that is well adapted to harsh climatic conditions. It is an interesting source of food ingredients in the normal diet and of food industry. The present study aims at evaluating the some physical and morphological parameter cactus cultivars fruit, besides the phytochemical, antioxidant and antimicrobial activities of methanolic and ethyl acetate extract of four Opuntiaficus-indica cultivars. The present results revelead that the highest levels of phenol found in the ethyl acetate extract of Sanguinea and methanolic extract of Ain Jemaa. While ethyl acetate extract Ain Jemaa displayed significant elevated concentrations of total flavonoids and flavonols as compared with other cultivars. The findings of this study show that methanolic crude extracts exhibited a considerably broader antimicrobial activity compared to ethyl acetate extracts. The Moroccan cultivar has displayed the best antioxidant and antibacterial activity.The antioxidant activity found in juice extract of Marocoand Algeriacultivars are the highest,and is mainly due to beta-carotene, as demonstrated by principal component analysis, allowing the useof these fractions as sources of natural antioxidants.
Keywords: Opuntiaficus-indica;Juice;Sugar; Phenolic compounds; Antioxidant activity; Antimicrobial activity.
The cactus belongs to the Cactaceae family which is native to arid and semi-arid regions (Shetty, Rana, and Preetham 2012). About 1500
species of cactus are in the genus Opuntiaand are
distributed in Europe, Mediterranean countries, Africa, southwestern United States, northern Mexico and other areas. Because cactus pear can withstand prolonged drought, it is considered as a
potential alternative crop for dry regions (Shetty, Rana, and Preetham 2012; Duru & Turker, 2005).
Cactus pear fruit is a many-seeded berry with a thick peel, enclosing a flavored seedy pulp. Although used as forage, cactus pear fruit is primarily consumed as a fresh commodity. Many
species of Opuntiaproduce edible and highly
fruit can be considered as a nutraceutical and functional food of high importance thanks to its high content of beneficial chemicals. Cactus is also known for its diuretic and relaxant effects on the renal tract (Sáenz, Estévez, Sepúlveda,
& Mecklenburg, 1998; Piga 2004; Vieira et al.
2008). Moreover, in many arid areas, farmers use cactus extensively not only as forage to prevent the disastrous consequences of droughts, but also as a source of water for livestock (Gebremariam, Melaku, and Yami 2006). There is increasing evidence that fruits and vegetables may protect against numerous diseases.
Their protective effect has generally been attributed to their antioxidant constituents, phenolic compounds, as well as to some minor components found in seed-oil and seed-protein contents. The nutritional importance of cactus pear fruit emanates mainly from the content of ascorbic acid, fibers and free amino acids (Stintzing, Schieber, and Carle 2001). Furthermore, (Ramadon& Morsel 2003) reported that cactus seed oil contains essentially unsaturated fatty acids (ca. 76%) and an appreciable level of fat-soluble vitamins. In many countries, cactus fruit and cactus pear juice is consumed at home or in restaurants. The processing of cactus pear fruit to obtain juices and other kinds of processed foods in order to increase the shelf-life of the fresh fruit has been studied in recent years
(Sáenz et al. 1996).
The aim of this work is to determine some characteristics of such fruit and juice and to study the antioxidant, antibacterial and antifungal
activities of four Opuntiaficus-indicafruit cultivars
growing in the same region. This evaluation will be important to select the best cultivar for the producers and certainly for the consumers.
MATERIALS AND METHODS
Chemicals
Solvents were purchased from Riedel-de-Haën™, Bucharest, Romania. Beta-carotene, Catechin, Gallic acid, Rutin, Tween, and linoleic acid were obtained from Fluka, Bucharest, Romania.
Collection of plant materials
The fruit of four Opuntia cultivars
were harvested randomly from at least three trees from FAO collection, Kairouan
(35° 402 North 10° 052 East of Tunisia), the average temperature ranges between 5 and 21 ° C in winter and between 25 and 42 ° C in summer. The annual rainfall is between 250 and 400 mm. The cultivars were: Sanguinea (Italy), Lengissima (Algeria), AinJemaa-(Morocco) and Ain Amara (Tunisia).
Some Physical Fruit Properties of Cactus Pear cultivars
The fruit diameter and length were determined using calipers. The fruits werewashed ;prickles and glochids on the peel surface were removed under running tap water by scrubbing. After water drained from the fruits, their weight were recorded. Fruits were cut longitudinally, the flesh peel weresegregated from pulp, and the weights of these parts were recordedthen the precentage of pulp wieght to the whole fruit were calculated. Seeds were washed under running water several times on a sieve (700 micron) to separate the seeds from the pulp. They were dried at room temperature and weighed. The dried seeds number were counted.The pulp weight was calculated by subtracting the fruit wieght from wet-seed weight and skin weight.Aslothe percentage of seeds to pulp were calculated.
Determination of total sugars in different parts of Cactus Pear cultivars
The sugar content for fruit juice were tested using the colorimetric method described by Miller (1959)using dinitrosalicylic acid as a reagent. Then sugar content were calculated per fruit.
Extraction procedures
The Opuntiaficus-indica extract was
Estimation of Total Phenolic, Total Flavonoid and Total Flavonol Contents in extracts
The total polyphenols were determined by the Folin-Ciocalteau procedure, using gallic acid as standard. The absorbance was measured at
765nm according to Li et al. (2007).The amount
of the total flavonoids in the extracts was measured
using the method described by (Djeridane et al.,
2006). This method is based on the formation of a complex flavonoid_aluminium, having the maximum absorbance at 510nm. Catechin was used as standard for the calibration curve. The flavonols content were determined as reported by (Miliauskasa and Venskutonisa, 2004). The absorbance was measured at 440nm and the rutin was used as standard for the calibration curve.
HPLC- (UV/SPD-10Avp) Quantitative Analysis of Cactus Pear cultivars extracts
HPLC chromatography was used for the separation of phenols from fruit extracts as
described by Bouaziz et al. (2008). The device
(Shimadzu) consists of a pump (LC-10ATvp) and a UV detector (SPD-10Avp). The column used is a column C-18 alkyl silica (4.6 ìm x 250 mm) Shim-pack VP-ODS.Each sample is filtered on 0.2 microns and then driven under pressure in
the column filled with a stationary phase of small particle size, by a high-pressure liquid (mobile phase), which reduces the time required to separate the components present in the stationary phase; these components thus have less time to diffuse into the column which produces narrower peaks and therefore better selectivity and sensitivity.The mobile phase used is 0.1% phosphoric acid (PA) (Prolabo, France) in water versus 70% acetonitrile (ACT) (Dharmadrug, GmbH, Germany) in water for total duration of 50 min. The elution conditions applied for the phenolic compounds are:0-25 min, 10-25% B; 25-35 min, 25-80% ACT; 35-37 min, 80-100% ACT; 37-40 min, 100% ACT, andfinally washing and equilibration of the column require (40-50 min) with linear gradient 100-10% ACT. The flow rate is 0.6 ml / min and the injection volume of 50 µl. The eluates were detected at 280 nm and the temperature is maintained at 40°C.
Gas chromatography/mass spectrometry (GC/ MS) analysis
GC-MS analysis of Ain Amara extract (Tunisia) were performed to evaluate the concentration of the active compounds separated with HPLC; using a Trace gas chromatograph interfaced to a Polaris Q mass spectrometer
Table 1. Percentage extract yield offour Opuntiaficus-indica cultivars
Solvent Ain Amara Lengissima Ain Jemaa Sanguinea (Tunisia) (Algeria) (Moraco) (Italy)
Ethyl acetate 0.2 0.31 0.30 0.04
Methanol 15.01 1.40 4.55 6.13
Table 2. Some Physical Fruit Propertiesof four Opuntiaficus-indica cultivars
Parameters Ain Amara Lengissima Ain Jemaa Sanguinea
(Tunisia) (Algeria) (Moraco) (Italy)
Length (cm) 7.29 ± 0.56a 6.62 ± 0.26b 6.85 ± 0.26 b 6.95 ± 0.67 b
Diameter (cm) 4.77 ± 0.36 a 4.17 ± 0.20 b 4.51 ± 0.22c 4.13 ± 0.19 b
Fresh Fruit weight (g) 99.67 ± 10.90 a 68.84 ± 10.23b 70.07 ± 14.11 b 82.17 ± 13.37c
Fresh Pulp weight (g) 71.27 ± 8.06 a 27.16 ± 3.94 b 37.28 ± 7.43 c 42.68 ± 6.87d
Fresh Peel weight (g) 28.42 ± 2.94 a 41.67 ± 6.31b 33.25 ± 6.62 c 39.48 ± 6.59 b
Pulp (%) 71.62 ± 0.23 a 39.38 ± 0.62b 53.24 ± 0.54c 51.96 ± 0.94d
Number of seeds 237.0 ± 24.95 a 235.0 ± 29.16 a 141.0 ± 29.09b 250.0 ± 37.63c
Dry weight of Seeds(g) 2.00±0.21 a 1.96±0.28 a 1.27±0.23a 2.11±0.35 a
Seed/plup (%) 2.87 ± 0.38 a 7.22 ± 0.39b 3.94 ± 0.34c 4.90± 0.85d
Volume of Juice (ml) 28.6 ± 2.83a 19.50 ± 3.96 b 28.00 ± 4.87 a 25.34 ± 3.90 c
Table 3. Mean values of sugar content from four Opuntiaficus-indica cultivars
Parameters Ain Amara Lengissima Ain Jemaa Sanguinea (Tunisia) (Algeria) (Moraco) (Italy)
Juice (g/l) 153.6 ± 1.63 a 215.0± 2.00b 76.8± 2.00c 122.8± 6.11d
Fruit (g/fruit) 6.16 ± 0.02a 15.44± 0.02b 5.77± 0.02a 7.29± 0.05a
Values are means ± SD. Different letters in each row indicate significant difference (P< 0.05) among means of different cultivars
Table 4. Mean values of total polyphenols, flavonoids, and flavonols from Ethyl acetate extractsof four Opuntiaficus-indica cultivars
Parameters Ain Amara Lengissima Ain Jemaa Sanguinea (Tunisia) (Algeria) (Moraco) (Italy)
TP (mg GAE /100g) 1.50 ±0.25 a 0.50 ±0.25b 1.00 ±0.04 c 2.20 ±0.45 d
TF (mg CE /100g) 57.00 ±1.25 a 42.00 ±2.00 b 65.00 ±0.17 c 56.00 ±1.52 d
TFL (mg RE /100g) 7.80 ±0.37 a 9.10 ±1.52 b 9.70 ±0.68 b 2.50±0.68 c
Values are means ± SD. Different letters in each row indicate significant difference (P< 0.05) among means
of different cultivars. (TP) total polyphenols, (TF)total flavonoids, (TFL)total flavonols, (GAE) Galic acid
equivalent, (CE) Catechin equivalent , (RE) Retin
Table 5. Mean values of total polyphenols, flavonoids, and flavonols from methanol extractsof four Opuntiaficus-indica cultivars
Parameters Ain Amara Lengissima Ain Jemaa Sanguinea
(Tunisia) (Algeria) (Moraco) (Italy)
TP (mg GAE /100g) 1.89±0.02 a 2.45±0.20b 2.53±0.06b 0.80 ±0.35c
TF (mg CE /100g) 26.13±0.02 a 30.00 ±2.64 b 31.61±1.41 b 34.19±2.08 b
TFL (mg RE /100g) 1.20 ±0.20 a 1.40 ±0.20 a 0.90 ±0.15 b 1.50 ±0.25 a
Values are means ± SD. Different letters in each row indicate significant difference (P< 0.05) among means of
different cultivars. (TP) total polyphenols, (TF)total flavonoids, (TFL)total flavonols, (GAE) Galic acid equivalent,
(CE) Catechin equivalent , (RE) Retin
(Thermo Finnigan, Hertfordshire, UK) as
previously described Chien et al. (2009) at the
Centre of Biotechnology of Sfax, Tunisia. For GC-MS detection, an electron ionization system with ionization energy of 70eV was used. Helieum gas (99.99%) was used as a carrier gas at a constant flow rate of 1.51ml/min. injector and mass transfer line temperature were set at 200 and 240°C respectively. The oven temperature was programmed from 70to 220°C at 10°C/min, held isothermal for 1min and finally raised to 300°C AT 10°C/min. 2µl of respective diluted samples was manually injected in the split less mode, with split ratio of 1:40 and with mass scan of 50-600 amu. Total running time of GC-MS is 35min. The relative percentage of the each extract
constituents was expressed as percentage with peak area normalization.The identification of the components was based on the comparison of their mass spectra with spectrometer database (Wiley and NIST Libraries i.e library sources were used for matching the identified components from the plant material) and confirmed by determination of their Kovats indices, which were calculated relative to the retention times (Stein, 1990).
Evaluation of the antioxidant activity by â-carotene
Table 6. Evaluation of the antibacterial and antifungal activities of methanol extracts of juices from Opuntiaficus-indica cultivars of using Agar diffusion method
Parameters Ain Amara Lengissima Ain Jemaa Sanguinea
(Tunisia) (Algeria) (Moraco) (Italy)
Staphylococcus aureus 27.00±2.47 a 24.00±1.16 a 29.00±2.06 a 25.00±1.66 a
Escherchia coli 0.00±0.00 a 0.00±0.00 a 0.00±0.00 a 0.00±0.00 a
Salmonella enterica 0.00±0.00 a 0.00±0.00 a 17.00±2.47b 16.00±2.47b
Pseudomonas aeruginosa 17.00±1.44 a 17.00±1.25 a 19.00±0.95 b 20.00±1.92 b
Bacillus subtilis 6.00±0.63 a 6.00±0.68 a 6.00±1.05 a 7.00±1.21 a
Candida albicans 15.00±0.91 a 13.00±1.05 a 0.00±0.00b 15.00±1.25 a
Aspergillus niger 15.00±2.05 a 17.00±2.05b 12.00±1.85c 14.00±1.35 a
Values are means ± SD. Different letters in each row indicate significant difference (P< 0.05) among means of different cultivars.
Table 7. Evaluation of the antibacterial and antifungal activities of ethyl acetate extracts of juices from Opuntiaficus-indica cultivars of using Agar diffusion method
Parameters Ain Amara Lengissima Ain Jemaa Sanguinea
(Tunisia) (Algeria) (Moraco) (Italy)
Staphylococcus aureus 14.00±1.77a 12.00±0.98b 11.00±1.37 b 13.00±1.47 a
Escherchia coli 10.00±0.61 a 10.00±0.56 a 10.00±0.77 a 11.00±0.40 a
Salmonella enterica 0.00±0.00 a 10.00±0.50b 10.00±1.17 b 10.00±0.81 b
Pseudomonas aeruginosa 0.00±0.00 a 0.00±0.00 a 0.00±0.00 a 0.00±0.00 a
Bacillus subtilis 10.00±0.86 a 0.00±0.00b 10.00±0.56 a 10.00±0.63 a
Candida albicans 12.00±1.15 a 0.00±0.00b 0.00±0.00b 0.00±0.00b
Aspergillus niger 16.00±1.07 a 17.00±2.01 a 16.50±1.54 a 15.00±1.11 a
Values are means ± SD. Different letters in each row indicate significant difference (P< 0.05) among means of different cultivars.
A â-carotene solution was prepared by dissolving 2 mg of â-carotene in 10 mL of chloroform. 1 mL of this solution was then pipetted into a round-bottom flask. After the removal of chloroform under vacuum, using a rotary evaporator at 40 °C, 20 mg of linoleic acid, 200 mg of Tween 80 emulsifier and 50 mL of oxygenated distilled water were added to the flask, which was shaken vigorously. The Aliquots (5 mL) of this prepared emulsion were transferred into a series of glass vials containing
200 ppm of each extract or 200 ppm of 2,6-di-tert
-butyl-4-methylphenol (BHT), which were used as a positive control for comparative purposes. As soon as the emulsion was added to each vial, the zero time absorbance was read at 470 nm. Absorbance readings were then recorded at 15 min intervals until the control sample had changed color. The absorbance was then recorded at hourly intervals until the color of â-carotene in the experimental samples had disappeared. During the experiment,
all samples were kept in a water bath at 50 °C. Absorbance decreased rapidly in the samples without an antioxidant, whereas in the presence of an antioxidant, they retained their color, and thus absorbance became longer.
DPPH radical-scavenging effect assay
The DPPH (1,1-diphenyl-2-picryl hydrazyl) radical scavenging effect was evaluated according to the method described by Bouaziz and Sayadi (2005). 4 ml of methanolic solution of varying sample concentration (25, 50, 100, and 150 µg/ml) was added to 10 ml of DPPH methanol
solution (1.5 10-4 M). The mixture was shaken
vigorously and placed for 30 min in the dark at room temperature. Then, the absorbance at 520 nm was measured using a Shimadzu UV-160 A spectrophotometer. BHT was used as thepositive control. The antioxidant activities were expressed in terms of the required concentration, inhibiting
Fig. 1. The fruits of four different cultivars of Opuntiaficus-indica Antimicrobial activity of four
Opuntiaficus-indica cultivars extracts using Agar diffusion
method
The antibacterial activity of
Opuntiaficus-indica juice extracts were tested against five strains of bacteria and fungi, kindly provided by Pr. AbdelhafidhDhouib from the Tunisian microbial collection (CTM) of the Center of Biotechnology,
Sfax-Tunisia: Staphylococcus aureus (CTM 50
257), Pseudomonas aeruginosa (CTM 50 258),
Escherichia coli (CTM 50 259), Salmonella enterica (CTM 50 260) and Bacillus subtilis (CTM 50 261). The antifungal activity was tested using
Aspergillusniger (CTM 10 099) and Candida albican (CTM 30 031).
Methanol and ethyl acetate extracts (100 µl) were dissolved in 100% dimethylsulfoxide (DMSO) (900 µl). The culture suspension (200
µl) of the tested microorganisms (106
colony-forming units (cfu/ml) of bacteria cells (estimated
by absorbance at 600 nm) and 108 spores/ml of
fungal strains (measured by Malassez blade) were spread on PCA medium and PDA medium, respectively. Then, wells (7 mm diameter) were made using a sterile borer and loaded with 100 µl of Opuntiaficus-indica juice extracts at 100 mg/ ml. A well with only 100 µl of DMSO (without extract) was used as a negative control. Gentamycin and Neomycin were used as positive references for
bacteria. The Petri dishes were kept, first for 1 h at
4°C (Hajji et al. 2010), and then incubated for 24
h at 37 °C for bacteria and 72 h at 30 °C for fungal strains. The antimicrobial activity was evaluated by measuring the diameter of the inhibition zones in millimeters (including well diameter of 7 mm). The measurements of the inhibition zones were carried out for three sample replications and the values are the averages of three replicates.
Statistical analysis
The values were expressed as mean and standard deviation of three parallel measurements. The data were evaluated by a one-way analysis of variance followed by Tukey HSD test, using SPSS V.20.0 software (SPSS Institute Inc., Cary, NC). Data considered statistically significant when p < 0.05.(Field, 2004).
RESULTS
Physical Fruit Properties of Cactus Pear cultivars
Fig. 2. Chromatogram (HPLC-UV/SPD-10Avp) of the methanolic and ethyl acetate extract of four Opuntiaficus-indica cultivars (50 min)
weight and pulp% as compared to those collected from the other locations. Furthermore, AinAmara samples possessed the highest extract juice volume (28.6±2.83 ml). the length of fruits from the other locations (Algeria, Moraco,Italy) were statistically
Fig. 3. GC-MS chromatogram of ethyl acetate extract of Tunisian cultivar
Fig. 4. Oxidation of emulsified linoleic acid/â-carotene catalysed by BHT and ethyl acetate extract of four Opuntiaficus-indica cultivars
peel weights of the different locations ranged from 28.42 g to 41.67 g, with the Algeria (Lengissima) fruit samples having highest value. The same trend detected for percentage of seed/pulp. Regarding number of seeds; Italy (Sanguinea) showed the highest value and displayed significant different as compared with other cultivars.
Total sugar content
The levels of total sugar determined in
juice and fruit offour Opuntiaficus-indica cultivars
Fig. 5. Oxidation of emulsified linoleic acid/â-carotene catalysed by BHT and methanolic extract of four Opuntiaficus-indica cultivars
Fig. 6. DPPH radical scavenging activity four Opuntiaficus-indica cultivars. Data were expressed as Mean ± Standard Deviations (SD). Values differ significantly at P < 0.05
and in fruit (g) from 5.77 to 15.44. Lengissima (Algeria) displayed the highest total sugar content either in juice and fruit and showed a significant different as compared with the other cultivars.
Total Phenolic, Total Flavonoid and Total Flavonol Contents in extracts
Studies of the quantitative composition of cultivarsextractsrevealed the presence of high
concentrations as compared with other cultivars. While methanolic extract of Sanguinea (Italy) showed significant highest concentrations of Flavonoids and flavonolsas compared with other cultivars.
Chromatogram (HPLC-UV/SPD-10Avp) of the methanol and acetate extractof cactus pear fruit juice
Separation of Compounds by High Performance Liquid Chromatography (HPLC)
In order to study the composition of the crude extracts obtained with the two organic solvents, were analyzed.Figure 2 shows, for the methanolic extracts of Tunisian and Algerian cultivars, similar profiles, while the Moroccan and Italian cultivars have different profiles. The chromatograms in diferent cultivars extracts showed a group of peaks that appear during the first 15 minutes, other less resolved peaks come out at the end, after 35 minutes. We notice a first peak (A) at 6 minutes, common to all profiles. A second peak (B) eluted at a retention time of 9 min is common to both spectra of Tunisian and Algerian cultivars only. Like a third peak (C) that comes out at 14 minutes.
With regard to the ethyl acetate extracts, the chromatograms have a different appearance. Tunisian shows a profile that differs from that of other cultivars, it has three peaks at the beginning of the spectrum (14 min).The other three cultivars have only one peak (D) out at 14 minutes.
Thus the methanolic extracts contain a wider variety of compounds than the ethyl acetate extracts. The two solvents did not extract the same molecules, the methanol selected the more polar compounds that come out on the chromatogram at the beginning of the spectrum.Instead, ethyl acetate dissolved more non-polar compounds eluted later and less well separated. At the beginning of the spectra, however, the peak common to the four cultivars (A), which appears at 14 minutes, was found interesting, to us to identify this product which would probably be responsible for the biological activities.
Analysis of the ethyl acetate extract of c. by Gas Chromatography Coupled to Mass Spectrometry (GC / MS)
We chose the ethyl acetate extract where there is the most abundant common peak (peak D) in figure 2, which is the case of the extract of
Tunisian cultivar. We then sought to analyze this extract by coupling gas chromatography with mass spectrometry which allows the identification of the constituent compounds.It turns out that the major compound identified in the ethyl acetate extract of the fruit juice of Ain Amaracultivar is a phenolic compound: caffeic acid (peak 2, 73.70%) in figure 3. The second less abundant compound belonging to the same family is 4-hydroxyphenyl ethanol (peak 1; 0.381%). Other identified compounds correspond to saturated or unsaturated long-chain fatty acids such as hexadecanoic acid (peak 3), octadecanoic acid (peak 4), and oleic acid (peak 5). Finally, peak X originates from an experimental impurity from using plasticequipments.
Antioxidant activity
The evaluation of the antioxidant activity by â-carotene method has affirmed that the result of the sample extracts is close to that of BHT. The obtained results have demonstrated that the activity methanol extract of Sanguinea and AinJemaa decreases after 30min , while the ethyl acetate extract activity maintains the same level as that of BHT and even exceeds beyond 50min
DPPH is a free radical compound that has been widely used to determine the free radical-scavenging ability of various sample extracts. The DPPH radical scavenging effect for methanol and ethyl acetate extracts of four cultivars is shown in Figure ( 4 and 5). The results indicated as relative activities against the control (BHT). The relative activities of all extracts are high, between 66.0±2.0 % and 81.61±1.73 %, so they exhibit antioxidant activity at a similar level to that of BHT (84%). In addition, the relative activities of ethyl acetate were slightly higher than those of methanol for all cultivars. The maximum activity for methanolic extracts of cultivars juice were found in Algerian and Italine cultivars as compared with others and the minimum activity was observed in Moracain type. Radical scavenging activity of ethyl acetate extracts displayed non significantdiffence among the four types of cultivars.
Antimicrobial activity of methanolic and ethyl acetate extracts
Staphylococcus aureus and the inhibition zone demonstrates larger diameters than those obtained with other bacteria (27.00±2.47, 24.00±1.16, 29.00±2.06and 25.00±1.66)forTunisia, Algeria, Moraco and Italy respectively. These values are the most highly recorded in comparison with other tested bacteria. The Moroccan cultivar has displayed the best antibacterial activity. The ethyl acetate extract also exhibits positive tests against
Staphylococcus aureus, and the diameter of the inhibition zone were (14.00±1.77, 12.00±0.98, 11.00±1.37 and 13.00±1.47) forTunisia, Algeria, Moraco and Italy respectively. Regarding both
strains, Pseudomonas aeruginosa and Bacillus
subtilis, the four methanolic extracts have shown moderately positive tests that.While, the inhibition diameter of neomycin against these two strains proves to be 25mm and 21mm, respectively. It can be noted that the ethyl acetate extract does not have
any action against Pseudomonas aeruginosa and
shows a positive action against Bacillus subtilis.
With respect to Salmonella enterica, the
Tunisian and Algerian methanolic extracts appear to have no more activity, while the Moroccan and Italian extracts prove to have an antibacterial power. On applying ethyl acetate extract, the Tunisian samples are found to show no more activity, while the other samples turn out to have
inhibitive power face to Salmonella enteric.
Escherchia coli resists to all methaolic- extract samples. However, ethyl acetate extracts show a
positive test against Escherchia coli.
The obtained results clearly highlight the persistence of a positive action of the sample extracts against the yeast and fungal species, except for the pertinent Ainjemaa extract. However, our extract seems not to show any resistance against
Aspergillus Niger , contrarily to Candida albicans, in which the extract action has the ability to resist.
DISCUSSION
The physical characteristics of the Cactus Pear fruits reported Tables 2. The analysis of the various morphological parameters studied shows that the Tunisian cultivar has the most favourable criteria: it has the fruit of larger size (length 7.29 cm and width 4.77 cm) and thus had the highest fresh weight. The percentage of the pulp compared to the whole fruit is 71.62%. On the other hand, the
peel has the lowest percentage (28.38%), as well as that of the seeds in relation to the pulp (2.87%). Regarding fruit mass Arba (2004)reported same weight ranges for some Moroccan varieties as in our results. Moreover, Stintzing, Schieber, and Carle 2003) reported that the fruit mass of some South African varieties vary from 83 g to 194 g
Also,Felker et al. (2005) reported that in Argentina,
the cactus fruit mass is between 112 and 212 g. Indeed, many authors (Karababa, Coskuner, and Asay 2004) have suggested that the size of cactus pear fruit is influenced by the region, season and environment. Nevertheless, other authors have confirmed that cactus fruit size is controlled by
genetic factors (Peter Felker et al. 2002).
Concerning, the fruit pulp percentage the present results displayed that Ain Amara was noticeably higher than AinJemaa and Sanguinea.
Felker et al. (2005) reported that the pulp
percentage of some varieties from Mexico and Argentina is between 40 % and 60 %. Indeed, the fruit pulp percentage may be due to the differences in cultivating practices, geographic location and climate conditions. It has been reported that during maturation, a higher rainfall can increase the pulp percentage, while a lower temperature
can decrease the pulp percentage (Peter Felker et
al. 2002; Lorenzo et al. 2008). The current results
support the effect of cultivar on the fruit size and pulp percentage.
With regard to seeds, the current study revealed that Sanguinea presented the highest content of seeds with 4.9 % of fruit; followed by Ain Amara and Lengissima. while AinJemaa, the seed content displayedthe lowest value. This result in contrary with Pimienta-Barrios (1994) who reported a value between 10 and 15 %. Indeed, these differences can explain the FAO collection of the cultivars.
The volume of juice is an important parameter of the quality of the fruit.The juice volumes recorded in the four cultivars (harvested in August) are close to that of prickly cactus harvested in (July-August) from the region of Kasserine (24.68 ml / fruit) studied by El-Guizani
and precipitation in October-November.
Regarding total sugar content in the cactus
fruit; Piga et al. (1996) reported that reducing
sugar in cultivar from Italy is from 10 to 15 %.
Indeed, the fruit of Opuntia sp. is considered as a
very sweet fruit, which is due to the presence of reducing sugars in the pulp, especially glucose and fructose (Russel&Felker 1987; Stintzing, Schieber, and Carle 2003).From the above results it could be mentioned that the highest content of total sugar represented in Algeria cultivar followed by Tunisia. These variation may be explained as mentioned by Carle (2003).
A previous study showed that there are many types of polyphenols in plant, and various phenolic molecular structures exhibited different
antioxidant activities (Agati et al., 2012). Currently,
many researchers and dietary organizations are recommending an increase of the consumption of fruits and vegetables that contain natural
antioxidant (Moure et al. 2001; Bazzano et al.
2002). Phenols are a major group of antioxidant phytochemicals with interesting properties for animal or human health. They display a remarkable group of biological and pharmacological activities
(Ihme et al. 1996).
The solvent has an effect on the polyphenol content of the extract (Do et al., 2014). The phenolic compounds are polar compounds and the methanol is the most polar solvent and the most appropriate to extract the total phenol, this
in agreement with our results (Roby et al., 2013).
The above results revealed that; methanol extract of different cultivars displayed higher content of the total phenols as compared with ethyl acetate. Moreover, The majority phenolic compound found in the fruit pulp ethyl acetate extract of the cultivar of Opuntiaficus-indica is caffeic acid. The second least abundant of the same family compound was detected is 4-hydroxyphenyl ethanol. Other acids long-chain saturated and unsaturated were also identified as hexadecanoic acid, oleic acid,
octadecanoic acid and hexanoic acid. Stintzing et
al. (2001) reported that Cactaceae had low content
of polyphenols. Moreover, Chavez-Santoscoy, et
al. (2009) told that the total phenolic compounds
are between 2.2 and 22.6 mg GAE /100g for some cactus species from Mexico.
Nonetheless, our results have shown that the content of flavonoids extracted with ethyl
acetate higher than the one obtained with methanol. Moreover, the content of flavonols extracted using ethyl acetate is higher than that extracted with methanol in the tested cultivars. These results may be explained by the fact that cactus juice is rich in moderately polar flavonoids which are probably more soluble in ethyl acetate than methanol. This is in agreement with the results found by other
authors (Stintzing et al. 2005) who reported that a
considerable diversity of methods exists to assess these antioxidants in plant tissues.
Flavonoids can act as antioxidants, enzyme inhibitors, pigments that allow the absorption of light and are responsible for coloring
in nature (Ninfali et al., 2007). The flavonoid
contents of the ethyl acetate extracts are higher (41.61 to 65.16 EC mg / 100g), and more variable in cultivar to the other. This result is unexpected since the flavonoids which make up half of the phenolic compounds (Hertog, 1995) are polar compounds and are usually extracted with methanol or water. This proves that the juice of prickly pear is rich in medium polar flavonoids and therefore more soluble in ethyl acetate.
Flavonols represent a group of flavonoids responsible for yellow, brown, and even white colors of flowers and fruits of plants.The contents of the methanolic extracts are less than those of the ethyl acetate extracts, they fluctuate from 1.10 to 1.56 mg EqRutin/ 100 g of extract. While with ethyl acetate, they reach 2.44 to 9.64 mg EqRutin/ 100 g Italian cultivars has the lowest and almost similar flavonol values, with both extraction solvents.
Thus, the polyphenols of the prickly pear juice of the four cultivars appear to be different in their content and their extractability with respect to the two solvents used, especially for Italian. Flavonoids, including flavonols, are better extracted with ethyl acetate. Some flavonoid activities are generally due to flavonols with several hydroxyl groups that have defense functions:
antioxidant activity (Rice-Evans et al., 1996) and
antimicrobial activity (Chattopadhay et al., 2001).
(Figure 6, table 6) It was noted that the migration of deposits extracted with the fruit pulp ethyl acetate extract of Opuntiaficus-indica, F5
and F’5-5 (Bargougui et al. 2014) have the same
the antileishmanial and antitrypanosomal activities
of the extract, F5 and F’5 (Bargougui et al. 2014)
are either the activity of caffeic acid or the activity of â-sitosterol.
lants rich in secondary metabolites, including phenolics, flavonoids and carotenoids, have antioxidant activity due to their redox properties and chemical structures. The extract of
cactusfruit juice cultivars had strong antioxidant activity. The DPPH radical is widely used in assessing free radical scavenging activity because of the ease of the reaction.
Indeed, due to the different antioxidant potentials of the different compounds, the antioxidant activities of the extract strongly
depend on the extraction solvent (Jang et al.
2007). antioxidant activity of phenolics is mainly due to their redox properties which make them act as reducing agents, hydrogen donors, singlet oxygen quenchers. These properties may also have
a metallic chelating potential (Rice-Evans, et al.,
1996).
The above results show that the activity of methanol extracts reveal positive tests against
Staphylococcus aureus and the inhibition zone demonstrates larger diameters than those obtained with other bacteria. The Moroccan cultivar has displayed the best antibacterial activity. The ethyl acetate extract also exhibits positive tests against
Staphylococcus aureus.
Regarding both strains, Pseudomonas
aeruginosa and Bacillus subtilis, the four methanolic extracts have shown moderately positive activity. It can be noted that the ethyl acetate extract does not have any action against
Pseudomonas aeruginosa and shows a positive
action against Bacillus subtilis. This results in
agreement with Ammar et al. (2012) who reported
that different cultivars of Opuntiaficu -indicaare
more active than the flowers hexane extract against
Pseudomonas aeruginosa, Esherchia coli and
Staphylococcus aureus.
With respect to Salmonella enterica, the
Tunisian and Algerian methanolic extracts appear to have no more activity, while the Moroccan and Italian extracts prove to have an antibacterial power. On applying ethyl acetate extract, the Tunisian samples are found to show no more
activity, while the other samples turn out to have
inhibitive power face to Salmonella enteric.
Concerning antimicrobial activity of cactus extracts, our findings confirm those reported
by Bussmann et al. (2010) for Opuntiaficusindica
collected in the North of Peru. Where Escherchia
coli resists to all methaolic- extract samples.
As well as the results obtainedfrom exposure of
Escherchia coli to ethyl acetate extract.
The obtained results clearly highlight the persistence of a positive action of the sample extracts against the bacterial and fungal species, except for the pertinent Ainjemaa extract. However, our extract seems not to show any resistance
against Aspergillus Niger for more than two days,
contrarily to Candida albicans, in which the extract
action has the ability to resist for more than two days.
In the present work, the
Opuntiaficus-indica extract appears to be more active than those
reported by (Ammar et al. 2012)with regard to the
flowers’ extract of the same species, especially
against Aspergillus Niger and Candida albicans.
It is noteworthy to mention that our results prove that the most effective extract against the studied microorganisms turns out to be the same extract which possesses the best antioxidant activity for Opuntiaficus-indica. Consequently, it is confirmed that the bioactive compounds important level, other than the phenolic compounds, is the one responsible for these biological properties. Indeed, many authors have substantiated that these compounds have an antibacterial effect (Ahmad
and Beg 2001; Rodriguez et al.; 2009; Taguri, et
al., 2006).
Actually, the phenolic compounds have the ability to act at two different levels, namely, the cell membrane and cell wall of the
microorganisms(Taguri, et al., 2006). In fact, they
can interact with the membrane proteins, affect the membrane permeability and lead to cell destruction. Besides, they can penetrate into bacterial cells and coagulate their content. In addition, the phenolic compounds are widely known to be synthesized by plants in response to microbial infection (Doughari,
El-Mahmood, and Tyoyina 2008; Sengul et al.
CONCLUSIONS
The results of the present study have shown a large difference in fruit, pulp and juice characteristics of the four different cultivars of
Opuntiaficus-indica. It is worthy to highlight that the present research contributes to demonstrate that the prickly pears potential plays an important role as a source of natural antioxidants, antibacterial and antifungal.
The antioxidant activity of cultivars may be due to presence of phenolic compounds which are the major contributor of the antioxidant capacities of these plants. Further research is needed in order to find the important bioactive compounds and if the in vitro results correlate with animal studies.
ACkNOwLEDGEMENTS
The authors would like to thank the director of the FAO station for the precious help in collecting the samples.
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